EP0979276B1

EP0979276B1 - Complement receptor type 1 (cr1)-like sequences

Info

Publication number: EP0979276B1
Application number: EP98910864A
Authority: EP
Inventors: Danuta E.I. SmithKline Beechaam Ph. MOSSAKOWSKA; Vivienne Frances Cox; Richard Antony Godwin Smith
Original assignee: Adprotech PLC
Current assignee: Adprotech PLC
Priority date: 1997-03-05
Filing date: 1998-03-05
Publication date: 2006-12-13
Anticipated expiration: 2018-03-05
Also published as: ATE348156T1; EP0979276A1; DE69836629D1; JP2001516212A; US20030064431A1; AU6509098A; GB9704519D0; WO1998039433A1; US6833437B2

Abstract

Replacement of codons in DNA encoding the first three SCRs of LHR-A of CR1 with others encoding the predicted amino acids in the CR1-like sequence can give rise to chimeric genes which can be expressed to give active complement inhibitors with functional complement inhibitory, including anti-haemolytic activity. There is provided a soluble polypeptide comprising, in sequence, one to four short consensus repeats (SCR) selected from SCR 1, 2, 3 and 4 of long homologous repeat A (LHR-A) as the only structurally and functionally intact SCR domains of CR1 and including at least SCR3, in which one or more of the native amino acids are substituted with the following: Val 4, Asp 19, Scr 53, Lys 57, Ala 74, Asp 79, Arg 84, Pro 91, Asn 109, Lys 116, Val 119, Ala 132, Thr 137, Ile 139, Ser 140, Tyr 143, His 153, Leu 156, Arg 159, Lys 161, Lys 177, Gly 230, Ser 235, His 236.

Description

This invention relates to novel polypeptides and their derivatives which act as inhibitors or regulators of complement activation and are of use in the therapy of diseases involving complement activation such as various inflammatory and immune disorders.
Constituting about 10% of the globulins in normal serum, the complement system is composed of many different proteins that are important in the immune system's response to foreign antigens. The complement system becomes activated when its primary components are cleaved and the products alone or with other proteins, activate additional complement proteins resulting in a proteolytic cascade. Activation of the complement system leads to a variety of responses including increased vascular permeability, chemotaxis of phagocytic cells, activation of inflammatory cells, opsonization of foreign particles, direct killing of cells and tissue damage. Activation of the complement system may be triggered by antigen-antibody complexes (the classical pathway) or, for example, by lipopolysaccharides present in cell walls of pathogenic bacteria (the alternative pathway).
Complement activation (CA) is known to occur in a wide variety of acute inflammatory processes particularly those associated with ischaemia and reperfusion injury (Rossen et al., 1985 Circ. Res., 57, 119,; Morgan B.P., 1990 The biological effects of complement activation. In 'Complement, Clinical Aspects and Relevance to Disease'. Academic Press. London.)
It is also generally accepted that at least some of the components of the classical complement cascade can be detected by immunohistochemical methods in close association with senile plaques in the brains of sufferers from Alzheimer's disease (Eikelenboom et al., 1994, Neuroscience, 59, 561-568) and that complement activation plays a role in the inflammatory component of this condition..
Complement receptor type 1 (CR1) has been shown to be present on the membranes of erythrocytes, monocytes/macrophages, granulocytes, B cells, some T cells, splenic follicular dendritic cells, and glomerular podocytes. CR1 binds to the complement components C3b and C4b and has also been referred to as the C3b/C4b receptor. The structural organisation and primary sequence of one allotype of CR1 is known (Klickstein et al., 1987, J. Exp. Med. 165:1095-1112, Klickstein et al., 1988, J. Exp. Med. 168:1699-1717; Hourcade et al., 1988, J. Exp. Med. 168:1255-1270, WO 89/09220, WO 91/05047). It is composed of 30 short consensus repeats (SCRs) that each contain around 60-70 amino acids. In each SCR, around 29 of the average 65 amino acids are conserved. Each SCR has been proposed to form a three dimensional triple loop structure through disulphide linkages with the third and first and the fourth and second half-cystines in disulphide bonds. CR1 is further arranged as 4 long homologous repeats (LHRs) of 7 SCRs each. Following a leader sequence, the CR1 molecule consists of the N-terminal LHR-A, the next two repeats, LHR-B and LHR-C, and the most C-terminal LHR-D followed by 2 additional SCRs, a 25 residue putative transmembrane region and a 43 residue cytoplasmic tail.
Based on the mature CR1 molecule having a predicted N-terminal glutamine residue, hereinafter designated as residue 1, the first four SCR domains of LHR-A are defined herein as consisting of residues 2-58, 63-120, 125-191 and 197-252, respectively, of mature CR1.
Hourcade et al., 1988, J. Exp. Med. 168:1255-1270 observed an alternative polyadenylation site in the human CR1 transcriptional unit that was predicted to produce a secreted form of CR1. The mRNA encoded by this truncated sequence comprises the first 8.5 SCRs of CR1, and encodes a protein of about 80 kDa which was proposed to include the C4b binding domain. When a cDNA corresponding to this truncated sequence was transfected into COS cells and expressed, it demonstrated the expected C4b binding activity but did not bind to C3b (Krych et al., 1989, FASEB J. 3:A368; Krych et al. Proc. Nat. Acad. Sci. 1991, 88, 4353-7). Krych et al., also observed a mRNA similar to the predicted one in several human cell lines and postulated that such a truncated soluble form of CR1 with C4b binding activity may be synthesised in humans.
In addition, Makrides et al. (1992, J. Biol. Chem. 267 (34) 24754-61) have expressed SCR 1 + 2 and 1 + 2 + 3 + 4 of LHR-A as membrane-attached proteins in CHO cells.
Several soluble fragments of CR1 have also been generated via recombinant DNA procedures by eliminating the transmembrane region from the DNAs being expressed (WO 89/09220, WO 91/05047). The soluble CR1 fragments were functionally active, bound C3b and/or C4b and demonstrated Factor I cofactor activity depending upon the regions they contained. Such constructs inhibited in vitro complement-related functions such as neutrophil oxidative burst, complement mediated hemolysis, and C3a and C5a production. A particular soluble construct, sCR1/pBSCR1c, also demonstrated in vivo activity in a reversed passive Arthus reaction (WO 89/09220, WO 91/05047; Yeh et al., 1991, J. Immunol. 146:250), suppressed post-ischemic myocardial inflammation and necrosis (WO 89/09220, WO 91/05047; Weisman et al., Science, 1990, 249:146-1511; Dupe, R. et al. Thrombosis & Haemostasis (1991) 65(6) 695.) and extended survival rates following transplantation (Pruitt & Bollinger, 1991, J. Surg. Res 50:350; Pruitt et al., 1991 Transplantation 52; 868). Furthermore, co-formulation of sCR1/pBSCR1c with p-anisoylated human plasminogen-streptokinase-activator complex (APSAC) resulted in similar anti-haemolytic activity as sCR1 alone, indicating that the combination of the complement inhibitor sCR1 with a thrombolytic agent was feasible (WO 91/05047).
In a model of antibody-mediated demyelinating experimental allergic encephalomyelitis (ADEAE), systemic inhibition of CA using sCR1 over 6 days, produced improvements in clinical score and blocked CNS inflammation, demyelination and deposition of complement components (Piddlesden et al., 1994, J. Immunol. 152, 5477). ADEAE can be regarded as a model of acute relapse in multiple sclerosis (MS) and these striking results suggested possible applications for sCR1 in MS therapy despite the high molecular weight (245 kilodaltons) of this agent.
In a rat model of traumatic brain injury, complement inhibitor sCR1 (also known as TP10 or BRL55730) was shown to reduce myeloperoxidase activity (an indicator of neutrophil accumulation) following traumatic injury (Kaczorowska et al, 1995, J. Cerebral Blood Flow and Metabolism, 15, 860-864). This is suggested as demonstrating that complement activation is involved in the local inflammatory response.
Soluble polypeptides corresponding to part of CR1 having functional complement inhibitory, including anti-haemolytic activity, have been described in WO94/00571 comprising, in sequence, one to four short consensus repeats (SCR) selected from SCR 1, 2, 3 and 4 of long homologous repeat A (LHR-A) as the only structurally and functionally intact SCR domains of CR1 and including at least SCR3.
Pseudogenes are usually defined as DNA sequences which possess a high degree of homology to genes with identified function but which are not expressed. The origins of the lack of transcription and translation vary but are commonly the presence of accumulated mutations which inactivate transcriptional initiation sites, disrupt RNA splicing or introduce frame-shift mutations and premature termination codons. Pseudogenes are sometimes regarded as genetic relics which have been isolated within the genome through a primary loss of expressability and which have subsequently mutated randomly in situ to highly aberrant forms. There is a frequent presumption that pseudogene sequences, if expressable at all, will not be functionally active because of an accumulation of deleterious in-frame mutations. However, studies of immune system genetics suggest that pseudogenes may act as a source of diversity in somatic mutation processes and that non-expressed sequences may recombine with normally expressed genes to create functional variants with a conserved framework. This phenomenon has been documented in immunoglobulin VL and VH genes and elsewhere (W.T.McCormack et al., Genes Dev. 4, 548-58, 1990).
The creation of pseudogenes through reverse transcription followed by DNA integration is also known. In such cases, the integrated sequences (which can in principle originate from organisms other than the host) lack introns and may be sited in chromosomal locations distant from the expressed gene to which they are homologous because integration into the genome can occur at random sites. Such genes are known as processed pseudogenes. The presence of pseudo genes in chromosomal clusters with homologous expressed genes argues against them being processed pseudogenes because of the improbability of a random integration process giving rise to close physical clustering in a large genome.
The existence of a gene homologous to that for complement receptor type 1 (CR1) was first reported by Hourcade et al. (J.Biol.Chem, 275, 974-80, 1990), who found it associated with a gene cluster on chromosome 1q 32 termed the Regulators of Complement Activation (RCA) cluster. The latter comprises the CR1 gene itself and those encoding decay accelerating factor (DAF), membrane cofactor protein (MCP), Factor H, complement receptor type 2 (CR2) and C4 binding protein. This 'CR1-like' gene was predicted to encode a protein containing seven SCR regions corresponding (by closest homology) to SCRs 1-6 and 9 of LHR-A (1-6) or LHR-B (9) of CR1 itself. The overall homology with the above regions of CR1 at the predicted amino acid level is 91% and the sequence divergence is greatest in the first three SCRs.
The CR1-like gene also encodes a signal peptide but not a transmembrane or cytoplasmic region and contains an intron-exon structure similar to the CR1 gene. There is currently no evidence that the CR1-like gene is expressed and neither mRNA transcripts nor a soluble protein have been isolated. The origin of the CR1-like sequence may lie in a gene duplication event in an ancestral CR1 gene which was followed by divergence and transcriptional inactivation of the CR1-like gene. It appears probable that the CR1-like gene is currently a pseudogene although not of the processed type.
It has now been found that replacement of codons in DNA encoding the first three SCRs of LHR-A of CR1 with others encoding the predicted aminoacids in the CR1-like sequence can give rise to chimeric genes which can be expressed to give active complement inhibitors with functional complement inhibitory, including anti-haemolytic, activity.
According to the present invention there is provided a soluble polypeptide comprising, in sequence, three short consensus repeats (SCR), one SCR selected from each of SCR 1, 2 and 3 of long homologous repeat A (LHR-A) as the only structurally and functionally intact SCR domains of CR1, in which ten of the native amino acids of SCR 3 are substituted with the following:

Ala 132, Thr 137, Ile 139, Ser 140, Tyr 143, His 153, Leu 156, Arg 159, Lys 161, Lys 177.

(Numbering is from glutamine as residue 1 of mature CR1. The amino-acid indicated is that which replaces the CR1 residue at the position specified.)

Additional features of the invention are defined in the attached claims.
In a preferred embodiment of formula (II)), the SCR3 region is substituted with the aforementioned Sequence Group 1 residues and the remaining domainshave the sequence of mature CRI.
In further preferred embodiments of formula (II), W², X², Y² and Z² represent residues 59-62, 121-124, 192-196, and residues 253 respectively, of mature CR1, optionally substituted as aforesaid, and V² represents residue i of mature CR1 optionally linked via its N-terminus to methionine.
In one particular embodiment of formula (II) arginine 235 is replaced by histidine.
In the preferred embodiment of formula (II), residue 235 is arginine.
The soluble polypeptides of the invention lack the membrane binding capability of the full length CR1 proteins which properties may be advantageous to the therapeutic activity.
The main classes of interaction of proteins with membranes can be summarised as follows:

1. Direct and specific interactions with phospholipid head groups or with other hydrophilic regions of complex lipids or indirectly with proteins already inserted in the membrane. The latter may include all the types of intrinsic membrane protein noted below and such interactions are usually with extracellular domains or sequence loops of the membrane proteins;
2. Through anchoring by a single hydrophobic transmembrane helical region near the terminus of the protein. These regions commonly present a hydrophobic face around the entire circumference of the helix cylinder and transfer of this structure to the hydrophilic environment of bulk water is energetically unfavourable.
3. Further anchoring is often provided by a short sequence of generally cationic aminoacids at the cytoplasmic side of the membrane, C-terminal to the transmembrane helix. The membrane-binding properties of CR1 are provided by features 2 and 3.
4. Through the use of multiple (normally 2-12 and commonly 4,7 and 10) transmembrane regions which are usually predicted to be helical or near-helical. Although these regions are normally hydrophobic overall, they frequently show some amphipathic behaviour - an outer hydrophobic face and an inner more hydrophilic one being identifiable within a helix bundle located in the lipid bilayer;
5. Through postranslationally linked phosphatidyl inositol moieties (GPI-anchors). These are generated by a specific biosynthetic pathway which recognises and removes a specific stretch of C-terminal aminoacids and creates a membrane-associating diacyl glycerol unit linked via a hydrophilic carbohydrate spacer to the polypeptide;
6. In a related process, single fatty acid groups such as myristoyl, palmitoyl or prenyl may be attached postranslationally to one or more sites in a protein (usually at Nor C-termini). Again, amino acids (such as the C-terminal CAAX box in Ras proteins) may be removed.

The present invention further provides a soluble derivative of the soluble polypeptide of the invention, said derivative comprising two or more heterologous membrane binding elements with low membrane affinity covalently associated with the polypeptide which elements are capable of interacting independently and with thermodynamic additivity with components of cellular membranes exposed to extracellular fluids.
By 'heterologous' is meant that the elements are not found in the native full length CR1 protein.
By 'membrane binding element with low membrane affinity' is meant that the element has significant affinity for membranes, that is a dissociation constant greater than 1µM, preferably 1µM-1mM. The elements preferably have a size <5kDa.
The derivative should incorporate sufficient elements with low affinities for membrane components to result in a derivative with a high (preferably 0.01 - 10nM dissociation constant) affinity for specific membranes. The elements combine so as to create an overall high affinity for the particular target membrane but the combination lacks such high affinity for other proteins for which single elements may be (low-affinity) ligands.
The elements should be chosen so as to retain useful solubility in pharmaceutial formulation media, preferably >100µg/ml. Preferably at least one element is hydrophilic.
The further embodiment of the invention thus promotes localisation of the polypeptide of the invention at cellular membranes and thereby provide one or more of several biologically significant effects with potential therapeutic advantages including:

Potency: an increase in effective concentration may result from the reduction in the diffusional degrees of freedom.
Pharmacokinetics and dosing frequency: Interaction of the derivatised polypeptide with long-lived cell types or serum proteins would be expected to prolong the plasma residence time of the polypeptide and produce a depot effect through deposition on cell surfaces.
Specificity: Many clinically important pathological processes are associated with specific cell types and tissues (for example the vascular endothelium and the recruitment thereto of neutrophils bearing the sialyl Lewis^x antigen to ELAM-1, see below). Hence targeting the modified polypeptide to regions of membrane containing pathology-associated membrane markers may improve the therapeutic ratio of the protein targeted.

It will be appreciated that all associations of heterologous amino acid sequences with the polypeptide will need to be assessed for potential immunogenicity, particularly where the amino acid sequence is not derived from a human protein. The problem can be minimised by using sequences as close as possible to known human ones and through computation of secondary structure and antigenicity indices.
The derivative preferably comprises two to eight, more preferably two to four membrane binding elements.
Membrane binding elements are preferably selected from: fatty acid derivatives such as fatty acyl groups; basic amino acid sequences; ligands of known integral membrane proteins; sequences derived from the complementarity-determining region of monoclonal antibodies raised against epitopes of membrane proteins; membrane binding sequences identified through screening of random chemical libraries.
The selection of suitable combination of membrane binding elements will be guided by the nature of the target cell membrane or components thereof.
Suitable fatty acid derivatives include myristoyl (12 methylene units) which is insufficiently large or hydrophobic to permit high affinity binding to membranes. Studies with myristoylated peptides (eg R.M.Peitzsch & S.McLaughlin, Biochemistry, 32, 10436-10443, 1993)) have shown that they have effective dissociation constants with model lipid systems of ~10^-4 M and around 10 of the 12 methylene groups are buried in the lipid bilayer. Thus, aliphatic acyl groups with between about 8 and 18 methylene units, preferably 10-14, are suitable membrane binding elements. Other examples of suitable fatty acid derivatives include long-chain (8-18, preferably 10-14 methylene) aliphatic amines and thiols, steroid and farnesyl derivatives.
Membrane binding has been found to be associated with limited (single-site) modification with fatty acyl groups when combined with a cluster of basic aminoacids in the protein sequence which may interact with acidic phospholipid head groups and provide the additional energy to target membrane binding. This combination of effects has been termed the 'myristoyl-electrostatic switch' (S.McLaughlin and A.Aderem, TIBS, 20,272-276, 1994; J.F.Hancock et al, Cell, 63, 133-139,1990). Thus, a further example of suitable membrane binding elements are basic aminoacid sequences such as those found in proteins such as Ras and MARCKS (myristoylated alanine-rich C-kinase substrate, P.J. Blackshear, J. Biol. Chem., 268, 1501-1504, 1993) which mediate the electrostatic 'switch' through reversible phosphorylation of serine residues within the sequence and a concomitant neutralisation of the net positive charge. Such sequences include but are not restricted to consecutive sequences of Lysine and Arginine such as (Lys)n where n is between 3 and 10, preferably 4 to 7.
Suitable examples of amino acid sequences comprising basic amino acids include:

i) DGPKKKKKKSPSKSSG
ii) GSSKSPSKKKKKKPGD
iii) SPSNETPKKKKKRFSFKKSG

(N-terminus on left)

Sequences i) to iii) are examples of electrostatic switch sequences.
Examples of amino acid sequences include RGD-containing peptides such as GRGDSP which are ligands for the α_libβ₃ integrin of human platelet membranes. Further examples of such sequences include those known to be involved in interactions between membrane proteins such as receptors and the major histocompatibility complex. An example of such a membrane protein ligand is the sequence GNEQSFRVDLRTLLRYA which has been shown to bind to the major histocompatibility complex class 1 protein (MHC-1) with moderate affinity (L.Olsson et al, Proc. Natl .Acad.Sci.USA. 91, 9086-909, 1994).
An example of a ligand for an integral membrane protein is the carbohydrate ligand Sialyl Lewis^x which has been identified as a ligand for the integral membrane protein ELAM-1 (M.L.Phillips et al, Science, 250, 1130-1132, 1990 & G.Walz et al, Ibid, 250, 1132-1135,1990).
Sequences derived from the complementarity-determining regions of monoclonal antibodies raised against epitopes within membrane proteins (see, for example, J.W.Smith et al, J.Biol.Chem. 270, 30486-30490, 1995) are also suitable membrane binding elements, as are binding sequences from random chemical libraries such as those generated in a phage display format and selected by biopanning operations in vitro (G.F.Smith and J.K.Scott, Methods in Enzymology, 217H, 228-257,1993) or in vivo (R.Pasqualini & E.Ruoslahti, Nature, 380, 364-366, 1996).
Optionally, conditional dissociation from the membrane may be incorporated into derivatives of the invention using mechanisms such as pH sensitivity (electrostatic switches), regulation through metal ion binding (using endogenous Ca²⁺, Zn²⁺ and incorporation of ion binding sites in membrane binding elements) and protease cleavage (e.g plasminolysis of lysine-rich membrane binding sequences to release and activate prourokinase)
Preferred derivatives of this invention have the following structure: $[P] - {\{L - [W]\}}_{n} - X$

in which:

P is the soluble polypeptide,
each L is independently a flexible linker group,
each W is independently a peptidic membrane binding element,
n is an integer of 1 or more and
X is a peptidic or non-peptidic membrane-binding entity which may be covalently linked to any W.

Peptidic membrane binding elements are preferably located sequentially either at the N or C terminus of the soluble polypeptide and are preferably 8 to 20 amino acids long. The amino acid sequences are linked to one another and to the soluble peptide by linker groups which are preferably selected from hydrophilic and/or flexible aminoacid sequences of 4 to 20 aminoacids; linear hydrophilic synthetic polymers; and chemical bridging groups.
In a further aspect, the invention provides a process for preparing a polypeptide according to the invention which process comprises expressing DNA encoding said polypeptide in a recombinant host cell and recovering the product.
In particular, the process may comprise the steps of:

i) preparing a replicable expression vector capable, in a host cell, of expressing a DNA polymer comprising a nucleotide sequence that encodes said polypeptide;
ii) transforming a host cell with said vector;
iii) culturing said transformed host cell under conditions permitting expression of said DNA polymer to produce said polypeptide; and
iv) recovering said polypeptide.

The DNA polymer comprising a nucleotide sequence that encodes the polypeptide also forms part of the invention.
The process of the invention may be performed by conventional recombinant techniques such as described in Sambrook et al., Molecular Cloning : A laboratory manual 2nd Edition. Cold Spring Harbor Laboratory Press (1989) and DNA Cloning vols I, II and III (D. M. Glover ed., IRL Press Ltd).
The invention also provides a process for preparing the DNA polymer by the condensation of appropriate mono-, di- or oligomeric nucleotide units.
The preparation may be carried out chemically, enzymatically, or by a combination of the two methods, in vitro or in vivo as appropriate. Thus, the DNA polymer may be prepared by the enzymatic ligation of appropriate DNA fragments, by conventional methods such as those described by D. M. Roberts et al., in Biochemistry 1985; 24, 5090-5098.
The DNA fragments may be obtained by digestion of DNA containing the required sequences of nucleotides with appropriate restriction enzymes, by chemical synthesis, by enzymatic polymerisation, or by a combination of these methods.
Digestion with restriction enzymes may be performed in an appropriate buffer at a temperature of 20°-70°C, generally in a volume of 50µl or less with 0.1-10µg DNA.
Enzymatic polymerisation of DNA may be carried out in vitro using a DNA polymerase such as DNA polymerase 1 (Klenow fragment) in an appropriate buffer containing the nucleoside triphosphates dATP, dCTP, dGTP and dTTP as required at a temperature of 10°-37°C, generally in a volume of 50µl or less.
Enzymatic ligation of DNA fragments may be carried out using a DNA ligase such as T4 DNA ligase in an appropriate buffer at a temperature of 4°C to 37°C, generally in a volume of 50µl or less.
The chemical synthesis of the DNA polymer or fragments may be carried out by conventional phosphotriester, phosphite or phosphoramidite chemistry, using solid phase techniques such as those described in 'Chemical and Enzymatic Synthesis of Gene Fragments - A Laboratory Manual' (ed. H.G. Gassen and A. Lang), Verlag Chemie, Weinheim (1982), or in other scientific publications, for example M.J.Gait, H.W.D. Matthes M. Singh, B.S. Sproat and R.C. Titmas, Nucleic Acids Research, 1982, 10, 6243; B.S. Sproat and W. Bannwarth, Tetrahedron Letters, 1983, 24, 5771; M.D. Matteucci and M.H. Caruthers, Tetrahedron Letters, 1980, 21, 719; M.D. Matteucci and M.H. Caruthers, Journal of the American Chemical Society, 1981, 103, 3185; S.P. Adams et al., Journal of the American Chemical Society, 1983, 105, 661; N.D. Sinha, J. Biernat, J. McMannus and H. Koester, Nucleic Acids Research, 1984, 12, 4539; and H.W.D. Matthes et al., EMBO Journal, 1984, 3, 801. Preferably an automated DNA synthesiser (for example, Applied Biosystems 381A Synthesiser) is employed.
The DNA polymer is preferably prepared by ligating two or more DNA molecules which together comprise a DNA sequence encoding the polypeptide.
The DNA molecules may be obtained by the digestion with suitable restriction enzymes of vectors carrying the required coding sequences.
The precise structure of the DNA molecules and the way in which they are obtained depends upon the structure of the desired product. The design of a suitable strategy for the construction of the DNA molecule coding for the polypeptide is a routine matter for the skilled worker in the art.
In particular, consideration may be given to the codon usage of the particular host cell. The codons may be optimised for high level expression in E. coli using the principles set out in Devereux et al., (1984) Nucl. Acid Res., 12, 387.
The expression of the DNA polymer encoding the polypeptide in a recombinant host cell may be carried out by means of a replicable expression vector capable, in the host cell, of expressing the DNA polymer. The expression vector is novel and also forms part of the invention.
The replicable expression vector may be prepared in accordance with the invention, by cleaving a vector compatible with the host cell to provide a linear DNA segment having an intact replicon, and combining said linear segment with one or more DNA molecules which, together with said linear segment, encode the polypeptide, under ligating conditions.
The ligation of the linear segment and more than one DNA molecule may be carried out simultaneously or sequentially as desired.
Thus, the DNA polymer may be preformed or formed during the construction of the vector, as desired. The choice of vector will be determined in part by the host cell, which may be prokaryotic, such as E. coli, or eukaryotic, such as mouse C127, mouse myeloma, chinese hamster ovary, fungi e.g. filamentous fungi or unicellular 'yeast' or an insect cell such as Drosophila. The host cell may also be in a transgenic animal. Suitable vectors include plasmids, bacteriophages, cosmids and recombinant viruses derived from, for example, baculoviruses or vaccinia.
The DNA polymer may be assembled into vectors designed for isolation of stable transformed mammalian cell lines expressing the fragment e.g. bovine papillomavirus vectors in mouse C127 cells, or amplified vectors in chinese hamster ovary cells (DNA Cloning Vol. II D.M. Glover ed. IRL Press 1985; Kaufman, R.J. et al.. Molecular and Cellular Biology 5, 1750-1759, 1985; Pavlakis G.N. and Hamer, D.H. Proceedings of the National Academy of Sciences (USA) 80, 397-401, 1983; Goeddel, D.V. et al., European Patent Application No. 0093619, 1983).
The preparation of the replicable expression vector may be carried out conventionally with appropriate enzymes for restriction, polymerisation and ligation of the DNA, by procedures described in, for example, Sambrook et al., cited above. Polymerisation and ligation may be performed as described above for the preparation of the DNA polymer. Digestion with restriction enzymes may be performed in an appropriate buffer at a temperature of 20°-70°C, generally in a volume of 50µl or less with 0.1-10µg DNA.
The recombinant host cell is prepared, in accordance with the invention, by transforming a host cell with a replicable expression vector of the invention under transforming conditions. Suitable transforming conditions are conventional and are described in, for example, Sambrook et al., cited above, or "DNA Cloning" Vol. II, D.M. Glover ed., IRL Press Ltd, 1985.
The choice of transforming conditions is determined by the host cell. Thus, a bacterial host such as E.coli, may be treated with a solution of CaCl₂ (Cohen et al., Proc. Nat. Acad. Sci., 1973, 69, 2110) or with a solution comprising a mixture of RbCl, MnCl₂, potassium acetate and glycerol, and then with 3-[N-morpholino]-propane-sulphonic acid, RbC1 and glycerol or by electroporation as for example described by Bio-Rad Laboratories, Richmond, California, USA, manufacturers of an electroporator. Mammalian cells in culture may be transformed by calcium co-precipitation of the vector DNA onto the cells or by using cationic liposomes.
The invention also extends to a host cell transformed with a replicable expression vector of the invention.
Culturing the transformed host cell under conditions permitting expression of the DNA polymer is carried out conventionally, as described in, for example, Sambrook et al., and "DNA Cloning" cited above. Thus, preferably the cell is supplied with nutrient and cultured at a temperature below 45°C.
The protein product is recovered by conventional methods according to the host cell. Thus, where the host cell is bacterial such as E. coli and the protein is expressed intracellularly, it may be lysed physically, chemically or enzymatically and the protein product isolated from the resulting lysate. Where the host cell is mammalian, the product is usually isolated from the nutrient medium.
Where the host cell is bacterial, such as E. coli, the product obtained from the culture may require folding for optimum functional activity. This is most likely if the protein is expressed as inclusion bodies. There are a number of aspects of the isolation and folding process that are regarded as important. In particular, the polypeptide is preferably partially purified before folding, in order to minimise formation of aggregates with contaminating proteins and minimise misfolding of the polypeptide. Thus, the removal of contaminating E. coli proteins by specifically isolating the inclusion bodies and the subsequent additional purification prior to folding are important aspects of the procedure.
The folding process is carried out in such a way as to minimise aggregation of intermediate-folded states of the polypeptide. Thus, careful consideration needs to be given to, among others, the salt type and concentration, temperature, protein concentration, redox buffer concentrations and duration of folding. The exact condition for any given polypeptide generally cannot be predicted and must be determined by experiment.
There are numerous methods available for the folding of proteins from inclusion bodies and these are known to the skilled worker in this field. The methods generally involve breaking all the disulphide bonds in the inclusion body, for example with 50mM 2-mercaptoethanol, in the presence of a high concentration of denaturant such as 8M urea or 6M guanidine hydrochloride. The next step is to remove these agents to allow folding of the proteins to occur. Formation of the disulphide bridges requires an oxidising environment and this may be provided in a number of ways, for example by air, or by incorporating a suitable redox system, for example a mixture of reduced and oxidised glutathione.
Preferably, the inclusion body is solubilised using 8M urea, in the presence of mercaptoethanol, and protein is folded, after initial removal of contaminating proteins, by addition of cold buffer. A preferred buffer is 20mM ethanolamine containing 1mM reduced glutathione and 0.5mM oxidised glutathione. The folding is preferably carried out at a temperature in the range 1 to 5°C over a period of 1 to 4 days.
If any precipitation or aggregation is observed, the aggregated protein can be removed in a number of ways, for example by centrifugation or by treatment with precipitants such as ammonium sulphate. Where either of these procedures are adopted, monomeric polypeptide is the major soluble product.
If the bacterial cell secretes the protein, folding is not usually necessary.
Peptide linkages in the derivatives of the invention may be made chemically or biosynthetically by expression of appropriate coding DNA sequences. Non peptide linkages may be made chemically or enzymatically by post-translational modification.
The polypeptide portion of the derivatives of the invention may be prepared by expression in suitable hosts of modified genes encoding the soluble polypeptide of the invention plus one or more peptidic membrane binding elements and optional residues such as cysteine to introduce linking groups to facilitate post translational derivatisation with additional membrane binding elements.
The polypeptide portion of the derivative of the invention may include a C-terminal cysteine to facilitate post translational modification. Expression in a bacterial system is preferred for proteins of moderate size (up to ~70kDa) and with <~8 disulphide bridges. More complex proteins for which a free terminal Cys could cause refolding or stability problems may require stable expression in mammalian cell lines (especially CHO). This will also be needed if a carbohydrate membrane binding element is to be introduced post-translationally. The use of insect cells infected with recombinant baculovirus encoding the polypeptide portion is also a useful general method for preparing more complex proteins and will be preferred when it is desired to carry out certain post-translational processes (such as palmitoylation) biosynthetically (see for example, M.J.Page et al J.Biol.Chem. 264, 19147-19154, 1989).
A preferred method of handling proteins C-terminally derivatised with cysteine is as a mixed disulphide with mercaptoethanol or glutathione or as the 2-nitro, 5-carboxyphenyl thio- derivative as generally described below in Methods.
Peptide membrane binding elements may be prepared using standard solid state synthesis such as the Merrifield method and this method can be adapted to incorporate required non-peptide membrane binding elements such as N-acyl groups derived from myristic or palmitic acids at the N terminus of the peptide. In addition activation of an amino acid residue for subsequent linkage to a protein can be achieved during chemical synthesis of such membrane binding elements. Examples of such activations include formation of the mixed 2-pyridyl disulphide with a cysteine thiol or incorporation of an N-haloacetyl group. Peptides can optionally be prepared as the C-terminal amide.
The derivatives of the invention may utilise a peptide membrane binding element comprising one or more derivatisations selected from:

a terminal cysteine residue optionally activated at the thiol group;
an N-haloacetyl group (where halo signifies chlorine, bromine or iodine) located at the N-terminus of the the peptide or at an ε-amino group of a lysine residue;
an amide group at the C-terminus; and
a fatty acid N-acyl group at the N-terminus or at an ε-amino group of a lysine residue.

Chemical bridging groups include those described in EP0109653 and EP0152736. The bridging group is generally of the formula:

-A-R-B- (V)

in which each of A and B, which may be the same or different, represents -CO-, -C(=NH₂ ⁺)-, maleimido, -S- or a bond and R is a bond or a linking group containing one or more -(CH₂)- or meta- or para- disubstituted phenyl units.
Where the polypeptide portion of the derivative of the invention and a peptidic membrane binding element both include a C-terminal cysteine the chemical bridging group will take the form -S-S-. The bridge is generated by conventional disulphide exchange chemistry, by activating a thiol on one polypeptide and reacting the activated thiol with a free thiol on the other polypeptide. Such activation procedures make use of disulphides which form stable thiolate anions upon cleavage of the S-S linkage and include reagents such as 2,2' dithiopyridine and 5,5'-dithio(2-nitrobenzoic acid, DTNB) which form intermediate mixed disulphides capable of further reaction with thiols to give stable disulphide linkages.
R may include moieties which interact with water to maintain the water solubility of the linkage and suitable moieties include -CO-NH-, -CO-NMe-, -S-S-, -CH(OH)-, -SO₂-, -CO₂-, -(CH₂CH₂-O)_m- and -CH(COOH)- where m is an integer of 2 or more.
Examples of R include -(CH₂)_r-, -(CH₂)_p-S-S-(CH₂)_q- and -(CH₂)_p-CH(OH)-CH(OH)-(CH₂)_q-, in which r is an integer of at least 2, preferably at least 4 and p and q are independently integers of at least 2.
The bridging group of formula (V) may be derived from a linking agent of formula (VI):

X-R₁-Y (VI)

in which R₁ is a linking group containing one or more -(CH₂)- units and X and Y are functional groups reactable with surface amino acid groups, preferably a lysine or cysteine group, or the N-terminal amino group, or a protein attachment group.
Preferred agents are those where X and Y are different, known as heterobifunctional agents. Each end of the agent molecule is reacted in turn with each polypeptide to be linked in separate reactions. Examples of heterobifunctional agents of formula (VI) include:

N-succinimidyl 3-(2-pyridyldithio) propionate
succinimidyl 4-(N-maleimido) caproate
3-(2-pyridyl) methyl propionimidate hydrochloride

In each case Y is capable of reacting with a thiol group on a polypeptide, which may be a native thiol or one introduced as a protein attachment group.
The protein attachment group is a functionality derived by modification of a polypeptide with a reagent specific for one or more amino acid side chains, and which contains a group capable of reacting with a cleavable section on the other polypeptide. An example of a protein attachment group is a thiol group. An example of a cleavable section is a disulphide bond. Alternatively the cleavable section may comprise an α, β dihydroxy function.
As an example, the introduction of a free thiol function by reaction of a polypeptide with 2-iminothiolane, N-succinimidyl 3-(2-pyridyldithio) propionate (with subsequent reduction) or N-acetyl homocysteine thiolactone will permit coupling of the protein attachment group with a thiol-reactive B structure. Alternatively, the protein attachment group can contain a thiol-reactive entity such as the 6-maleimidohexyl group or a 2-pyridyl-dithio group which can react with a free thiol in X. Preferably, the protein attachment group is derived from protein modifying agents such as 2-iminothiolane that react with lysine ε-amino groups in proteins.
When X represents a group capable of reacting directly with the amino acid side chain of a protein, it is preferably an N-succinimidyl group. When X represents a group capable of reacting with a protein attachment group, it is preferably a pyridylthio group.
In the above processes, modification of a polypeptide to introduce a protein attachment group is preferably carried out in aqueous buffered media at a pH between 3.0 and 9.0 depending on the reagent used. For a preferred reagent, 2-iminothiolane, the pH is preferably 6.5-8.5. The concentration of polypeptide is preferably high (> 10mg/ml) and the modifying reagent is used in a moderate (1.1- to 5-fold) molar excess, depending on the reactivity of the reagent. The temperature and duration of reaction are preferably in the range 0°-40°C and 10 minutes to 7 days. The extent of modification of the polypeptide may be determined by assaying for attachment groups introduced.
Such assays may be standard protein chemical techniques such as titration with 5,5'-dithiobis-(2-nitrobenzoic acid). Preferably, 0.5-3.0 moles of protein attachment group will be introduced on average per mole of polypeptide. The modified polypeptide may be separated from excess modifying agents by standard techniques such as dialysis, ultrafiltration, gel filtration and solvent or salt precipitation. The intermediate material may be stored in frozen solution or lyophilised.
Where a protein attachment group is introduced in this way, the bridging group (V) will be formed from a reaction of the linking agent (VI) and the protein attachment group.
The polypeptides to be linked are reacted separately with the linking agent or the reagent for introducing a protein attachment group by typically adding an excess of the reagent to the polypeptide, usually in a neutral or moderately alkaline buffer, and after reaction removing low molecular weight materials by gel filtration or dialysis. The precise conditions of pH, temperature, buffer and reaction time will depend on the nature of the reagent used and the polypeptide to be modified. The polypeptide linkage reaction is preferably carried out by mixing the modified polypeptides in neutral buffer in an equimolar ratio. Other reaction conditions e.g. time and temperature, should be chosen to obtain the desired degree of linkage. If thiol exchange reactions are involved, the reaction should preferably be carried out under an atmosphere of nitrogen. Preferably, UV-active products are produced (eg from the release of pyridine 2-thione from 2-pyridyl dithio derivatives) so that coupling can be monitored.
After the linkage reaction, the polypeptide conjugate can be isolated by a number of chromatographic procedures such as gel filtration, ion-exchange chromatography, affinity chromatography or hydrophobic interaction chromatography. These procedures my be either low pressure or high performance variants.
The conjugate may be characterised by a number of techniques including low pressure or high performance gel filtration, SDS polyacrylamide gel electrophoresis or isoelectric focussing.
Membrane binding elements which are fatty acid derivatives are attached post translationally to a peptidic membrane binding element, preferably at the terminus of the polypetide chain. Preferably, where the recombinant polypeptide portion of the derivative of the invention contains the peptidic membrane binding element, it has a unique cysteine for coupling to the fatty acid derivative. Where the recombinant polypeptide has a cysteine residue, a thiol-derivative of the fatty acid is added to the refolded recombinant protein at a late stage in purification (but not necessarily the final stage) and at a reagent concentration preferably below the critical micelle concentration. One of the fatty acid derivative and the recombinant peptide will have the thiol group activated as described above for thiol interchange reactions. The fatty acid derivative is preferably a fatty acyl derivative of an aminoC_2-6alkane thiol (optionally C-substituted) such as N-(2-myristoyl) aminoethanethiol or N-myristoyl L-cysteine.
Suitable examples of hydrophilic synthetic polymers include polyethyleneglycol (PEG), preferably α,ω functionalised derivatives, more preferably α-amino, ω-carboxy-PEG of molecular weight between 400 and 5000 daltons which are linked to the polypeptide for example by solid-phase synthesis methods (amino group derivatisation) or by thiol-interchange chemistry.
Membrane binding elements derived from ligands of known integral membrane proteins, either amino acid sequences or carbohydrates, may be generated by post-translational modification using the glycosylation pathways of eukaryotic cells targeted to N-linked glycosylation sites in the peptide sequence.
Convenient generic final stage purification strategies are hydrophobic interaction chromatography (HIC) on C2-C8 media and cation exchange chromatography for separation of derivatised and underivatised proteins into which a hydrophobic-electrostatic switch combination has been inserted.
In a further aspect, therefore, the invention provides a process for preparing a derivative according to the invention which process comprises expressing DNA encoding the polypeptide portion of said derivative in a recombinant host cell and recovering the product and thereafter post translationally modifying the polypeptide to chemically introduce membrane binding elements.
The invention also extends to DNA encoding the polypeptide portion of the derivative and to replicable expression vectors and recombinant host cells containing the DNA.
The polypeptide or derivative of this invention is useful in the treatment or diagnosis of many complement-mediated or complement-related diseases and disorders including, but not limited to, those listed below.

Disease and Disorders Involving Complement
Neurological Disorders
multiple sclerosis
stroke
Guillain Barré Syndrome
traumatic brain injury
Parkinson's disease
allergic encephalitis
Alzheimer's disease
Disorders of Inappropriate or Undesirable Complement Activation
haemodialysis complications
hyperacute allograft rejection
xenograft rejection
corneal graft rejection
interleukin-2 induced toxicity during IL-2 therapy
paroxysmal nocturnal haemoglobinuria
Inflammatory Disorders
inflammation of autoimmune diseases
Crohn's Disease
adult respiratory distress syndrome thermal injury including burns or frostbite
uveitis
psoriasis
asthma
acute pancreatitis
Kawasaki's disease
Post-Ischemic Reperfusion Conditions
myocardial infarction
balloon angioplasty
atherosclerosis (cholesterol-induced) & restenosis
hypertension
post-pump syndrome in cardiopulmonary bypass or renal haemodialysis renal ischemia
intestinal ischaemia
Infectious Diseases or Sepsis
multiple organ failure
septic shock
Immune Complex Disorders and Autoimmune Diseases
rheumatoid arthritis
systemic lupus erythematosus (SLE)
SLE nephritis
proliferative nephritis
glomerulonephritis
haemolytic anemia
myasthenia gravis
Reproductive Disorders
antibody- or complement-mediated infertility

Wound Healing

The present invention is also directed to a pharmaceutical composition comprising a therapeutically effective amount of a polypeptide or derivative, as above, and a pharmaceutically acceptable carrier or excipient. The subject is preferably a human.
An effective amount of the polypeptide or derivative for the treatment of a disease or disorder is in the dose range of 0.01-100mg/kg; preferably 0.1mg-10mg/kg.
For administration, the polypeptide or derivative should be formulated into an appropriate pharmaceutical or therapeutic composition. Such a composition typically contains a therapeutically active amount of the polypeptide or derivative and a pharmaceutically acceptable excipient or carrier such as saline, buffered saline, dextrose, or water. Compositions may also comprise specific stabilising agents such as sugars, including mannose and mannitol, and local anaesthetics for injectable compositions, including, for example, lidocaine.
Further provided is the use of a polypeptide or derivative of this invention in the manufacture of a medicament for the treatment of a disease or disorder associated with inflammation or inappropriate complement activation.
In order to inhibit complement activation and, at the same time, provide thrombolytic therapy, the present invention provides compositions which further comprise a therapeutically active amount of a thrombolytic agent. An effective amount of a thrombolytic agent is in the dose range of 0.01-10mg/kg; preferably 0.1-5mg/kg. Preferred thrombolytic agents include, but are not limited to, streptokinase, human tissue type plasminogen activator and urokinase molecules and derivatives, fragments or conjugates thereof. The thrombolytic agents may comprise one or more chains that may be fused or reversibly linked to other agents to form hybrid molecules (EP-A-0297882 and EP 155387), such as, for example, urokinase linked to plasmin (EP-A-0152736), a fibrinolytic enzyme linked to a water-soluble polymer (EP-A-0183503). The thrombolytic agents may also comprise muteins of plasminogen activators (EP-A-0207589). In a preferred embodiment, the thrombolytic agent may comprise a reversibly blocked in vitro fibrinolytic enzyme as described in U.S. Patent No. 4,285,932. A most preferred enzyme is a p-anisoyl plasminogen-streptokinase activator complex as described in U.S. Patent No. 4,808,405, and marketed under the Trademark EMINASE (generic name anistreplase, also referred to as APSAC; Monk et al., 1987, Drugs 34:25-49).
Routes of administration for the individual or combined therapeutic compositions of the present invention include standard routes, such as, for example, intravenous infusion or bolus injection. Active complement inhibitors and thrombolytic agents may be administered together or sequentially, in any order.

GENERAL METHODS USED IN EXAMPLES

(i) DNA Cleavage

Cleavage of DNA by restriction endonucleases was carried out according to the manufacturer's instructions using supplied buffers. Double digests were carried out simultaneously if the buffer conditions were suitable for both enzymes. Otherwise double digests were carried out sequentially where the enzyme requiring the lowest salt condition was added first to the digest. Once the digest was complete the salt concentration was altered and the second enzyme added.

(ii) DNA ligation

Ligations were carried out using T4 DNA ligase purchased from Promega, as described in Sambrook et al, (1989) Molecular Cloning: A Laboratory Manual 2nd Edition. Cold Spring Harbour Laboratory Press.

(iii) Plasmid isolation

Plasmid isolation was using Promega Wizard^™ Plus Minipreps or Qiagen Plasmid Maxi kit according to the manufacturer's instructions.

(iv) DNA fragment isolation

DNA fragments were excised from agarose gels and DNA extracted using the QIAEX gel extraction kit or Qiaquick, or GeneClean gel extraction kits according to the manufacturer's instructions (QIAGEN Inc., USA, Bio 101 Inc, USA).

(v) Introduction of DNA into E. coli

Plasmids were transformed into E. coli BL21(DE3) (Studier and Moffat, (1986), J. Mol. Biol 189:113) that had been made competent using calcium chloride as described in Sambrook et al, (1989). E. coli JM109 and XL1-blue strains were purchased as a frozen competent culture from Promega.

(vi) DNA sequencing

Plasmid DNA is sequenced on a Vistra DNA Labstation 625. The sequencing chemistry is performed using Amersham International's 'Thermo Sequenase fluorescent dye-terminator cycle sequencing kit' (RPN 2435), in conjunction with their 'FMP fluorescent dye-terminator precipitation kit' (RPN 2433) according to the manufacturer's instructions.
The sequences produced by the above procedure are analysed by a Perkin Elmer ABI Prism 377 DNA Sequencer. This is an electrophoretic technique using 36 cm x 0.2mm 4% acrylamide gels, the fluorescently labeled DNA fragments being detected by a charge coupled device camera according to the manufacturer's instructions.

(vii) Production of oligonucleotides

Oligonucleotides were purchased from Cruachem.

(viii) pBROC413

The plasmid pT7-7 [Tabor, S (1990), Current Protocols in Molecular Biology, F. A. Ausubel, Brent, R. E. Kingston, D. D. Moore, J. G. Seidman, J. A. Smith, and K. Struhl,eds.] pp.16.2.1-16.2.11, Greene Publishing and Wiley-Interscience,New York.] contains DNA corresponding to nucleotides 2065-4362 of pBR322 and like pBR322 can be mobilized by a conjugative plasmid in the presence of a third plasmid ColK. A mobility protein encoded by ColK acts on the nic site at nucleotide 2254 of pBR322 initiating mobilization from this point. pT7-7 was digested with LspI and BglII and the protruding 5' ends filled in with the Klenow fragment of DNA PolymeraseI. The plasmid DNA fragment was purified by agarose gel electrophoresis, the blunt ends ligated together and transformed into E. coli DH1 by electroporation using a Bio-Rad Gene Pulser and following the manufacturers recommended conditions. The resultant plasmid pBROC413 was identified by restriction enzyme analysis of plasmid DNA.
The deletion in pBROC413 from the LspI site immediately upstream of the f 10 promoter to the BglII site at nucleotide 434 of pT7-7 deletes the DNA corresponding to nucleotides 2065-2297 of pBR322. The nic site and adjacent sequences are therefore deleted making pBROC413 non mobilizable.

(ix) Sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS PAGE)

SDS PAGE was carried out generally using the Novex system (British Biotechnology) according to the manufacturer's instructions. Prepacked gels of acrylamide concentrations 4 - 20% were most frequently used. Samples for electrophoresis, including protein molecular weight standards (for example LMW Kit, Pharmacia or Novex Mark 12) were usually diluted in 1%(w/v)SDS - containing buffer (with or without 5%(v/v) 2-mercaptoethanol), and left at room temperature for about 0.5 h before application to the gel.

(x) Reduction of disulphides and modification of thiols in proteins

There are a number of methods used for achieving the title goals. The reasons it may be necessary to carry out selective reduction of disulphides is that during refolding, concentration and further purification of multi-thiol proteins inappropriate disulphide pairing can occur. In addition, even if correct disulphide paring does occur, it is possible that a free cysteine in the protein may become blocked with the reducing agent, for example glutathione. These derivatives are generally quite stable. In order to make them more reactive, for example for subsequent conjugation to another functional group, they need to be selectively reduced, with for example dithiothreitol (DTT) or with Tris (2-carboxyethyl) phosphine.HCl (TCEP) then optionally modified with a function which is moderately unstable. An example of the latter is Ellmans reagent (DTNB) which gives a mixed disulphide. In the case where treatment with DTNB is omitted, careful attention to experimental design is necessary to ensure that dimerisation of the free thiol-containing protein is minimised. Reference to the term 'selectively reduced' above means that reaction conditions eg. duration, temperature, molar ratios of reactants have to be carefully controlled so that disulphide bridges within the natural architecture of the protein are not reduced. All the reagents are commercially available eg. from Sigma or Pierce.
The following general examples illustrate the type of conditions that may be used and that are useful for the generation of free thiols and their optional modification. The specific reaction conditions to achieve optimal thiol reduction and/or modification are ideally determined for each protein batch.
TCEP may be prepared as a 20mM solution in 50mM Hepes (approx. pH 4.5) and may be stored at -40 degrees C. DTT may be prepared at 10mM in sodium phosphate pH 7.0 and may be stored at -40 degrees C. DTNB may be prepared at 10mM in sodium phosphate pH 7.0 and may be stored at -40 degrees C. All of the above reagents are typically used at molar equivalence or molar excess, the precise concentrations ideally identified experimentally. The duration and the temperature of the reaction are similarly determined experimentally. Generally the duration would be in the range 1 to 24 hours and the temperature would be in the range 2 to 30 degrees C. Excess reagent may be conveniently removed by buffer exchange, for example using Sephadex G25. A suitable buffer is 0.1M sodium phosphate pH7.0.

EXAMPLES

Example 1 Expression and isolation of CM7 (SEQ ID 1)

(a) Construction of plasmid pBrocSCR1-3CM7 encoding CM7

CM7 consists of the short consensus repeats 1 and 2 from the CR1 gene fused to the sequence of SCR3 from the CR1-like gene. The sequence of the DNA encoding CM7 is shown in seq ID No2. It was constructed using the plasmid coding for SCR1-3 (MQ1 - > K196) of CR-1, pDB1013-5 (Ref: patent application WO 94/00571). PDB1013-5 was subjected to site directed mutagenesis using a QuickChange kit suppled by Stratagene. Three pairs of oligonucleotides were utilised to introduce ten amino acid changes changes to the native SCR3 sequence corresponding to the changes observed in the CR-1 like pseudogene sequence described by Hourcade et al 1990 (Journal of Biological Chemistry 265, pp 974-980): Each pair of oligonucleotides is complementary in sequence. Changes are shown in lower case.
The first pair:

CGACCAT CgCCAACGGTGATTTC AcCTCTAtCAgTCGCGAGtATTTTCAC (SEQ ID No. 3) and
GTGAAAATaCTCGCGAcTGaTAGAGgTGAAATCACCGTTGGcGATGGTCG (SEQ ID No. 4)

The second pair:

GACCTACCaCTGCAATCtGGGTAGCcGTGGTaaaAAGGTGTTTGAGC (SEQ ID No. 5) and
GCTCAAACACCTTtttACCACgGCTACCCaGATTGCAGtGGTAGGTC (SEQ ID No. 6)

The third pair:

GCACTAGcAAaGACGATCAAGTGGG (SEQ ID No.7) and
CCCACTTGATCGTCt TTgCTAGTGC (SEQ ID No.8)

To generate DNA encoding CM7 all six oligonucleotides were used simultaneously in the mutagenesis reaction and transformed into competent XL1-Blue E. coli (Stratagene). Resulting colonies were grown up in LBroth and plasmids extracted using standard methodology. The plasmids were screened for sucessful mutagenesis by the loss of the ApoI or SpeI restriction sites or the acquisition of a new BsaJI restriction site. In the first experiment only the oligonucleotide pair (SEQ ID Nos. 7 and 8) were incorporated resulting in the loss of the SpeI restriction site. This plasmid (pBrocSCR1-3P3) was subjected to further rounds of site-directed mutagenesis using the oligonucleotides SEQ ID Nos 3,4, 5 and 6. From this was produced the mutated plasmid pBrocSC1-3P7 containing all ten amino acid coding changes in the SCR3 coding domain.
Using the restriction enzymes EcoRI and HindIII, the mutated SCR3 domain was excised from the plasmid pBrocSCR1-3P7 as a 229 base pair fragment and ligated back into a 2540 base pair EcoRI/HindIII fragment of pDB1031-5 containing vector and SCR1-2 sequences to minimise the possibility of unwanted mutations elsewhere in the plasmid. The resulting plasmid was pBrocSCR1-3CM7 encoding the protein CM7 (SEQ ID NO: 1).

(b) Expression of CM7 from pBrocSCR1-3CM7

pBrocSCR1-3CM7 was transformed into calcium chloride competent E. coli BL21(DE3) and resultant colonies were isolated and checked for plasmid content. To express protein from pBrocSCR1-3CM7 in E. coli BL21(DE3), a single colony was inoculated into 10 ml LB-phosphate media (20g/L tryptone, 15g/L yeast extract, 0.8g/L NaCl, 0.2g/L Na₂HPO₄, 0.1g/L KH₂PO₄) containing 50ug/ml ampicillin. The culture was grown for 6 hours at 37°C, 230 r.p.m. before being used to inoculate 100 ml of the same media containing 50 ug/ml ampicillin. Growth was under the same conditions overnight 25 ml of each culture were then used to inoculate 600 ml of the same media with 50 ug/ml ampicillin in 3 L Erlenmeyer flasks. Cells were grown to an OD of about 0.25 at A₆₀₀ nm. IPTG (isopropyl B-D galactopyranoside) was added to a final concentration of 1 mM and cells allowed to continue growth for a further about 8 hours before harvesting by centrifugation at 8000 g/10 min. Pellet from 2L of culture was stored at -40°C

(c) Isolation, refolding, purification and formulation of CM7

The methods described are essentially those detailed in Dodd I. et al (1995) Protein Expression and Purification 6 727-736 with some modifications.

(i) Isolation of solubilised inclusion bodies

The frozen cell pellet of E. coli BL21(DE3) (pBrocSCR1-3CM7) was allowed to thaw at room temperature for 2h and resuspended in 50 mM Tris/50 mM NaCl/1 mM EDTA pH 8.0 (approx. 60ml). The suspension was transferred to a glass beaker surrounded by ice and sonicated (Heat systems - Ultrasonics W380; 50 x 50% pulse, pulse time = 5 sec.) for 3 min. and then spun at 7000 rpm for 20 min. The supernatant was decanted and discarded The pellet was resuspended in 20 mM Tris/8M urea/1 mM EDTA/50 mM 2-mercaptoethanol pH 8.5 (80ml) at room temperature by vigorous swirling, then left for 1h at room temperature with occasional swirling.

(ii) Initial purification using SP-Sepharose

To the viscous solution was added SP-Sepharose FF (30g wet weight) that had been water washed and suction-dried. The mixture was swirled vigorously and left static for 1-2h at room temperature. The supernatant was decanted, sampled and discarded. The remaining slurry was resuspended to a uniform suspension and poured into a glass jacket and allowed to settle into a packed bed. The column was equilibrated with 0.02M Tris/8M urea/0.05M 2-mercaptoethanol/0.001 M EDTA pH 8.5.at room temperature. When the A₂₈₀ of the eluate had stabilised at baseline, the buffer was changed to equilibration buffer additionally containing 1M NaCl. A single A₂₈₀ peak was eluted by the 1M NaCl-containing buffer; the volume was approx. 40ml. The protein concentration of a sample of this solution that had been buffer-exchanged (Sephadex G25) into 50 mM formic acid was estimated by A₂₈₀ determination, using a molar extinction coefficient of 25000 cm^-1 and the formula A = ECL where A is the absorption of the solution at 280nm, E is the molar extinction coefficient, C is the molar concentration of protein and L is the light path in cm. This showed the product had a protein concentration of 0.44mg/ml. SDS PAGE showed that the product contained apparently two major species, both wih a molecular weight around 22 000. The solution was stored at -40°C.

(iii) Folding and further processing

The 40ml SP-Sepharose-purified product was added gradually over a 1 min period to 1240 ml freshly prepared, cold 0.06 M ethanolamine/1mM EDTA with continuous swirling, and left static for 1 h/4°C. Reduced glutathione (GSH) was added to 1 mM and oxidised glutathione (GSSG) was added to 0.5 mM by the addition of 100-fold concentrates of both solutions. The solution was clear and was left static approx 2-3°C for 5d. The solution was then ultrafiltered using a YM10 membrane to a final retentate volume of 59 ml; the retentate was clear and it was mixed with 9 vol. 0.1M NaH₂PO₄/1M (NH₄)₂S0₄ pH 7.0 (Buffer A) at room temperature and immediately centrifuged at 3000 rpm for 20 min. The supernatant was applied to a column (i.d.,26mm, h.,100mm) of Butyl Toyopearl 650M and the column was developed using a linear gradient of Buffer A to 0.1M sodium phosphate pH7.0. All the chromotography was at room temperature at 2 ml / min. A single A280-peak was noted during the gradient. The fractions spanning the peak were pooled and were ultrafiltered (YM10) to 2.5ml. This retentate was regarded as the product. The product contained one major species by non-reduced SDS PAGE with an estimated purity of >95% and an apparent molecular weight of 21 000. A sample of the product diluted 10-fold in 0.1M sodium phosphate pH7.0 had an A280 of 0.47; using an extinction coefficient of 34000 allowed the protein concentration to be calculated as 140uM. C18 Poros HPLC using a acetonitrile gradient in 0.08% TFA gave a single A215 peak with an estimated purity of approx. 99%. Electrospray mass spectrophotometry gave a mass of 21887.

Example 2 Expression and isolation of CM7/cys (SEQ ID NO 31)

Construction of plasmid pBrocSCR1-3CM7mutcys encoding CM7/cys.
The plasmid pBrocSCR1-3CM7mutcys was produced by site directed mutagenesis of pBrocSCR1-3CM7 using methods similar to those described in example 1. A pair of oligonucleotides with complementary sequence were used in which five changes to the sequence of pBrocSCR1-3CM7 had been introduced. Two of the changes introduced a unique ApaI restriction enzyme site without altering the amino sequence and three changes introduced a cysteine codon immediately prior to the stop codon. The sequences of the oligonuclotides used for the mutagenesis were as follows: Seq ID No. 32 CTGGAGCGGgCCcGCACCGCAGTGCATCATCCCGAACAAAtgcTAATAAAAGC, Seq ID No. 33 GCTTTTATTAgcaTTTGTTCGGGATGATGCACTGCGGTGCgGGcCCGCTCCAG. Following site directed mutagenesis and transfomation into competent E.coli, the resulting colonies were analysed by restriction enzyme digestion for the introduction of the new ApaI restriction site. DNA sequencing confirmed that the encoded amino acid sequence had been altered by the addition of a single C-terminal cysteine residue to give Seq ID No 31.

(ii) Expression and isolation of CM7/cys protein

CM7/cys was expressed in E. coli transformed with pBrocSCR1-3CM7mutcys using methods identical to those described for CM7 in Example 1. The cell pellet from 1L was stored at -40 degrees C until use.
The E. coli cell pellet was processed in exactly the same way as described for CM7 to obtain purified, concentrated protein for further evaluation. The final formulated protein product - the ultrafiltered retentate of the Butyl Toyopearl-eluted fractions - contained 12mg protein based on A280 determination using an extinction coefficient of 34000 and had an apparent molecular weight and purity on SDS PAGE gels (non-reduced) of 20000 and about 80% respectively.

Example 3 Preparation of [CM7]-Cys-S-S-[MSWP-1] (PM-9) (SEQ ID No. 34)

(i) Myristoyl/Electrostatic Switch Peptide Reagent 1 (MSWP-1) N-(Myristoyl) -Gly-Ser-Ser-Lys-Ser-Pro-Ser-Lys-Lys-Lys-Lys-Lys-Lys-Pro-Gly-Asp-(S-2-Thiopyridyl)Cys-NH₂

The peptide:

Gly-Ser-Ser-Lys-Ser-Pro-Ser-Lys-Lys-Lys-Lys-Lys-Lys-Pro-Gly-Asp-Cys-NH₂ (SEQ ID NO 35)

Coupling reactions were carried out using N-α-Fmoc protected reagents preactivated with N,N'-diisopropylcarbodiimide/ N-hydroxybenzotriazole (in 4-fold molar excess) with bromophenol blue monitoring. Fmoc cleavages used 20% piperidine in DMF. Reactions to assemble the peptide chain were carried out by repeated cycles of coupling and deprotection including the attachment of the modified Rink linkage reagent (p-[(R,S)-α-[1-(9H-fluoreny-9-yl-methoxyformamido]2,4 dimethoxybenzyl]-phenoxyacetic acid) designed to yield a C-terminal amide on final cleavage. The side chain functionalities of the individual amino-acids were protected as follows:

Ser (tButyl), Lys (Boc), Asp (O-tButyl), Cys (Trityl).

On completion of the peptide assembly and with the peptide still attached to the resin, the myristoyl group was attached to the amino group of the N terminal glycine by direct coupling of myristic acid by the same activation procedure. This modified peptide was then cleaved from the resin and the side-chain protecting groups removed at the same time by treatment with trifluoracetic acid containing 2.5% water and 2.5% triisopropyl silane.
The crude product was treated with 2,2' dithiopyridine in 0.01M ammonium acetate solution at pH 8-9 for approx. 2h, then acidified with acetic acid and purified by preparative high performance liquid chromatography (HPLC) in 0.1% trifluoracetic acid (TFA) /water and 0.1% TFA/acetonitrile as gradient component. After lyophilisation, the peptide was a white amorphous powder, soluble to at least 10mg/ml in dimethylsulphoxide. Fast atom bombardment mass spectrometry gave main peaks at m/e 2107.8, 2129.7 and 2145.8, corresponding to the monoprotonated, monosodiated and monopotassiated molecular ions of the peptide. The 2-thiopyridyl content of the peptide was measured by dissolving it to around 0.03mM to 0.2 mM in 0.1M Sodium Borate pH 8.0 and reducing by addition of dithiothreitol to 5mM. The change in optical density at 343nm was used to calculate the amount of pyridine 2-thione released using an extinction coefficient at this wavelength of 8080 cm^-1 M^-1. This indicated that the peptide content was approximately 60% of the dry weight.

(ii) Synthesis of PM9

CM7/cys from Example 4 (12uM; 0.1ml) was mixed with TCEP (Tris-(2-carboxyethyl) phosphine) (5mM; 0.001ml) and incubated at room temperature for 18 h. 0.01ml of 500mM ethanolamine was added and mixed. MSWP-1 from (i) (2mM in 0.1M sodium phosphate pH 7.0; 0.0014ml) was added and the solution incubated for a further 4 h. The prodcuct was analysed by SDS PAGE and showed two primary bands under non-reducing conditions, the major one with an apparent molecular weight of 20000 and a minor one of about 22000, the latter consistent with the formation of target PM9.

Example 4 Construction of plasmid pBrocSCR1-3CM7rgdcys encoding CM7/rgdcys.

This construct consists of the sequence of CM7 modified at the C-terminus of the protein to contain an RGD sequence as a ligand for Glyoprotein IIb/IIIa of platelets.
The plasmid pBrocSCR1-3CM7rgdcys was produced by restriction enzyme digestion of pBrocSCR1-3CM7mutcys with ApaI and HindIII and purification of the large fragment.
Two oligonucleotides were annealed in vitro and ligated into this fragment. The sequence of the inserted oligonucleotides was as follows. Seq ID No. 52
CGCACCGCAGTGCATCATCCCGAACAAAGATGGCCCGAGCGAAATTCTGCGT GGCGATTTTAGCAGCTGCTA and Seq ID No. 53:
AGCTTAGCAGCTGCTAAAATCGCCACGCAGAATTTCGCTCGGGCCATCTTTGT TCGGGATGATGCACTGCGGTGCGGGCC. The amino acid sequence of the encoded protein is shown in Sequence ID No. 54. The resulting colonies were analysed by restriction enzyme digestion and confirmed by DNA sequencing.

Example 5 Construction of plasmid pBrocSCR1-3CM7Tcell encoding CM7/Tcell.

This construct consists of the sequence of CM7 fused at the C-terminus to an extension designed to target the protein to the T-cell receptor alpha subunit.
The plasmid pBrocSCR1-3CM7Tcell was produced by restriction enzyme digestion of pBrocSCR1-3CM7mutcys with ApaI and HindIII and purification of the large fragment. Two oligonucleotides were annealed in vitro and ligated into this fragment. The sequence of the inserted oligonucleotides was as follows. Seq ID No. 55
CGCACCGCAGTGCATCATCCCGAACAAAGCGGCGCCCAGCGTGATTGGCTTC CGTATTCTGCTGCTGAAAGTGGCGGGCTGATA and Seq ID No. 56:
AGCTTATCAGCCCGCCACTTTCAGCAGCAGAATACGGAAGCCAATCACGCTG GGCGCCGCTTTGTTCGGGATGATGCACTGCGGTGCGGGCC. The amino acid sequence of the encoded protein is shown in Sequence ID No 57. The resulting colonies were analysed by restriction enzyme digetion and confirmed by DNA sequencing.

Biological Activity

(i) Anti-complement Activity Measured by the Classical Pathway-mediated Haemolysis of Sheep Erythrocytes

Functional activity of complement inhibitors was assessed by measuring the inhibition of complement-mediated lysis of sheep erythrocytes sensitised with rabbit antibodies (Diamedix Corporation, Miami, USA). Human serum diluted 1:125 or 1:100 in 0.1 M Hepes/0.15 M NaC1/0.1% gelatin pH 7.4 was used as a source of complement. The serum was prepared from a pool of volunteers essentially as described in Dacie & Lewis, 1975. Briefly, blood was warmed to 37°C for 5 minutes, the clot removed and the remaining serum clarified by centrifugation. The serum fraction was split into small aliquots and stored at -196°C. Aliquots were thawed as required and diluted in the Hepes buffer immediately before use.
Inhibition of complement-mediated lysis of sensitised sheep erythrocytes was measured using a standard haemolytic assay using a v-bottom microtitre plate format as follows:.
50 µl of a range of concentrations of inhibitor (typically in the region of 0.1 - 100 nM) diluted in Hepes buffer were mixed with 50 µl of the diluted serum and 100 µl of prewarmed sensitised sheep erythrocytes and then incubated for 1 hour at 37°C. Samples were spun at 1600rpm at ambient temperature for 3 minutes before transferring 150 µl of supernatant to flat bottom microtitre plates and determining the absorption at 410 nm.. Maximum lysis (Amax) was determined by incubating serum with erythrocytes in the absence of any inhibitor. Background lysis (Ao) was determined by incubating erythrocytes in the absence of any serum or inhibitor To check whether the inhibitor itself had any effect on lysis, erythrocytes were incubated with inhibitor alone; none of the compounds had any direct effect on lysis of the red blood cells. Inhibition was expressed as a fraction of the total cell lysis such that IH50 represents the concentration of inhibitor required to give 50% inhibition of lysis. $IH = \frac{A - Ao}{Amax - Ao}$

where 0 is equivalent to complete inhibition and 1 equals no inhibition.
The CM7 protein product of Example 1 inhibited complement-mediated lysis of sensitised sheep red blood cells with an IH50 of approx. 6 nM. In a separate experiment, CM7 and CM7/cys preparations gave IH50 values of about 20-30nM and they were experimentally indistinguishable from each other.

(ii) Anti-complement Activity Measured by Alternative Pathway-mediated Haemolysis of Guinea Pig Erythrocytes

Functional activity of complement inhibitors was assessed by measuring the inhibition of complement mediated lysis of guinea pig erythrocytes essentially as described by Scesney, S. M. et al (1996) J. Immunol. 26 1729-1735. The assay is designed to be specific for the alternative pathway of complement activation. Human serum prepared from a pool of volunteers essentially as described in Dacie & Lewis, 1975 wasused as the source of complement. Briefly, blood was warmed to 37°C for 5 minutes, the clot removed and the remaining serum clarified by centrifugation. The serum fraction was split into small aliquots and stored at -196°C. Aliquots were thawed as required and diluted in 0.1 M Hepes/ 0.15 M NaCl / 0.1% gelatin / 8 mM EGTA / 5 mM MgCl₂ pH 7.4 (buffer A) immediately before use. Guinea pig erythrocytes were prepared from guinea pig whole blood collected into EDTA-coated tubes as follows. The blood was spun at 1600 rpm for 5 min and the erythrocyte pellet washed 3 times with 0.1 M Hepes/ 0.15 M NaCl / 0.1% gelatin pH 7.4 until the supernatant of the spin was essentially colourless. The erythrocytes were finally resuspended to the original volume of blood used and were stored at + 4 degrees C. They were used within 2 weeks.
50 µl of a range of concentrations of inhibitor diluted in buffer A in a v-bottom microtitre plate were mixed with, first,100 µl of serum that had been diluted 1:3 and second, 50 µl of guinea pig erythrocytes (diluted 1:49 in buffer A) and incubated for 1 hour at 37°C.. The plate was spun at 1600 rpm for 3 minutes before transferring 150 µl of each supernatant to a flat bottom microtitre plate and determining the absorption at 405 mn, which reflects the amount of lysis in each test solution. Maximum lysis (Amax) was determined by incubating serum with erythrocytes in the absence of any inhibitor. Background lysis (Ao) was determined by incubating erythrocytes in the absence of any serum or inhibitor. To check whether the inhibitor itself had any effect on lysis, erythrocytes were incubated with inhibitor alone; none of the compounds had any direct effect on lysis of the red blood cells. The final dilution of serum used in the assay did absorb at 405nm but the level of absorbance (approx 10% of Amax) was considered to have a neglible affect on the overall assay results and it was ignored in the calculations. Inhibition was expressed as a fraction of the total cell lysis such that IH50 represents the concentration of inhibitor required to give 50% inhibition of lysis. $% inhibition = 1 - [(A - Ao) / (Amax - Ao)]$
CM7 final product similar to that described in Example 1 was assayed in the guinea pig haemolysis assay. In two separate assays the product inhibited haemolysis with IH50 values of 170nM and 180nM respectively.

(iii) Inhibition of zymosan A-induced activation of the alternative pathway by CM7.

The alternative pathway of complement was activated with zymosan A, a complex carbohydrate from yeast (Sigma, catalogue number Z-4250). Zymosan A was made 50 mg/ml in Hepes buffer (0.1M Hepes/0.15M NaCl pH 7.4) and vortexed until a fine suspension had formed. Human serum was preincubated with different concentrations of complement inhibitor diluted in Hepes buffer for 15 mins at 37°C using the volumes given below. Zymosan A was then vortexed for a few seconds each time before addition to the samples after which samples were incubated for a further 30 mins at 37°C. The zymosan A was then spun down at approximately 11,000g for 30 seconds at ambient temperature. 100 µl of supernatant were added to an equal volume of precipitating solution provided in the kit and assayed as described in the technical bulletin of Amersham with the C3a des Arg assay RIA kit purchased from Amersham International plc, U. K., (human complement C3a des Arg [¹²⁵I]assay, code RPA 518). In the C3a RIA Assay, activation of complement pathways can be followed by measuring the release of the anaphylatoxin, C3a and its breakdown product C3a des Arg. Both products can be measured using a competitive radio-immuno assay. Each sample was assayed in duplicate and a useful dilution was 1/100. Volumes of samples added

serum inhibitor Zymosan A

Normal Assay 89 µl 20 µl 21 µl
The data were computed essentially as described in the Amersham technical bulletin with the exception that the standard curve was not used and data were calculated only as B/Bo.
Controls included maximum activation (A) i.e. serum + zymosan A only, background activation (B) i.e. serum + buffer only and background activation in the presence of inhibitor (C) i.e. serum + inhibitor only. D is the value of activation of serum in the presence of inhibitor and zymosan A. These values could then be used to determine the % inhibition at each inhibitor concentration, using the following formula I. Note that the formula looks unusual because of the nature of the assay, in particular that because the assay is a competition assay all factors are inversed eg. maximum activation actually gives the lowest counts in the assay. $Formula I : \frac{D - A}{C - A} \times 100$
The IC50 is defined as the concentration of inhibitor required to reduce maximum activation by 50%. Using the data generated experimentally and reproduced in the table below, the IC50 for CM 7 of Example 1 was about 1µM and was indistinguishable from that of SCR1-3 prepared as described in WO94/00571

µM SCR1-3 CM7

21.5 106

15.4 87

5.4 59

3.8 65

1.35 54

0.96 43

0.34 15

0.24 17

0.084 7

0.06 6

0.021 -2

0.015 -3

SEQUENCE LISTING

SEQ ID No. 1 CM7 amino acid sequence
SEQ ID No. 2 CM7 DNA sequence
SEQ ID No. 3 DNA sequence
1 CGACCATCGC CAACGGTGAT TTCACCTCTA TCAGTCGCGA GTATTTTCAC
SEQ ID No. 4 DNA sequence
1 GTGAAAATAC TCGCGACTGA TAGAGGTGAA ATCACCGTTG GCGATGGTCG
SEQ ID No. 5 DNA sequence
1 GACCTACCAC TGCAATCTGG GTAGCCGTGG TAAAAAGGTG TTTGAGC
SEQ ID No. 6 DNA sequence
1 GCTCAAACAC CTTTTTACCA CGGCTACCCA GATTGCAGTG GTAGGTC
SEQ ID No. 7 DNA sequence
1 GCACTAGCAA AGACGATCAA GTGGG
SEQ ID No. 8 DNA sequence
1 CCCACTTGAT CGTCtTTgCT AGTGC
SEQ ID No. 9 CM1 amino acid sequence
SEQ ID No. 10 CM1 DNA sequence
SEQ ID No. 11 CM2 amino acid sequence
SEQ ID No. 12 CM2 DNA sequence
SEQ ID No. 13 CM3 amino acid sequence
SEQ ID No. 14 CM3 DNA sequence
SEQ ID No. 15 CM5 amino acid sequence
SEQ ID No. 16 CM5 DNA sequence
SEQ ID No. 17 CM6 amino acid sequence
SEQ ID No. 18 CM6 DNA sequence
SEQ ID No. 19 CM8 amino acid sequence
SEQ ID No. 20 CM8 DNA sequence
SEQ ID No. 21 CM9 amino acid sequence
SEQ ID No. 22 CM9 DNA sequence
SEQ ID No. 23 CM10 amino acid sequence
SEQ ID No. 24 CM10 DNA sequence
SEQ ID No. 25 CM12 amino acid sequence
SEQ ID No. 26 CM12 DNA sequence
SEQ ID No. 27 CM13 amino acid sequence
SEQ ID No. 28 CM13 DNA sequence
SEQ ID No. 29 CM14 amino acid sequence
SEQ ID No. 30 CM14 DNA sequence
SEQ ID No. 31 CM7/cys amino acid sequence
SEQ ID No. 32 DNA sequence
1 CTGGAGCGGG CCCGCACCGC AGTGCATCAT CCCGAACAAA TGCTAATAAA AGC
SEQ ID No. 33 DNA sequence
1 GCTTTTATTA GCATTTGTTC GGGATGATGC ACTGCGGTGC GGGCCCGCTC CAG
SEQ ID No. 34 CM7/Cys-S-S-[MSWP-1] amino acid sequence
SEQ ID No. 35: Amino acid sequence of peptide used in MSWP synthesis
1 Gly Ser Ser Lys Ser Pro Ser Lys Lys Lys
11 Lys Lys Lys Pro Gly Asp Cys NH₂
SEQ ID No. 36 CM15/cys amino acid sequence
SEQ ID No. 37 DNA sequence
1 CAGTGCAACG TGCCGGAATG G
SEQ ID No. 38 DNA sequence
1 CCATTCCGGA ACGTTGCACT G
SEQ ID No. 39 DNA sequence
1 GACTGATGAT TTTGAGTTCC
SEQ ID No. 40 DNA sequence
1 GGAACTCAAA ATCATCAGTC
SEQ ID No. 41 DNA sequence
1 GTCTGGACTA GTGCTAAGGA CAAGTGCAAA CGTAAATCTT GTCG
SEQ ID No. 42 DNA sequence
1 CGACAAGATT TACGTTTGCA CTTGTCCTTA GCACTAGTCC AGAC
SEQ ID No. 43 DNA sequence
1 CGGCATGGCG CATGTGATCA AAGATATCCA GTTCCGATCG CAAATTAAAT
51 ATTCTTGTCC TAAGGGTTAC CGTC
SEQ ID No. 44 DNA sequence
1 GACGGTAACC CTTAGGACAA GAATATTTAA TTTGCGATCG GAACTGGATA
51 TCTTTGATCA CATGCGCCAT GCCG
SEQ ID No. 45 DNA sequence
1 CATCTCTGGT AATACTGTCA TTTGGGATAA TAAAACACCG GTTTGTGACC
SEQ ID No. 46 DNA sequence
1 GGTCACAAAC CGGTGTTTTA TTATCCCAAA TGACAGTATT ACCAGAGATG
SEQ ID No. 47 DNA sequence
1 GACCGAATTA TCTGTGGTCT G
SEQ ID No. 48 DNA sequence
1 CAGACCACAG ATAATTCGGT C
SEQ ID No. 49 CM15/cys-MSWP1 amino acid sequence
SEQ ID No. 50 CM16/cys amino acid sequence
SEQ ID No. 51 CM16/cys-MSWP1 amino acid sequence
Seq ID No. 52 DNA sequence
1 CGCACCGCAG TGCATCATCC CGAACAAAGA TGGCCCGAGC GAAATTCTGC
51 GTGGCGATTT TAGCAGCTGC TA
Seq ID No. 53 DNA sequence
1 AGCTTAGCAG CTGCTAAAAT CGCCACGCAG AATTTCGCTC GGGCCATCTT
51 TGTTCGGGAT GATGCACTGC GGTGCGGGCC
SEQ ID NO. 54: CM7rgdcys amino acid sequence
Seq ID No. 55 DNA sequence
1 CGCACCGCAG TGCATCATCC CGAACAAAGC GGCGCCCAGC GTGATTGGCT
51 TCCGTATTCT GCTGCTGAAA GTGGCGGGCT GATA
Seq ID No. 56 DNA sequence
1 AGCTTATCAG CCCGCCACTT TCAGCAGCAG AATACGGAAG CCAATCACGC
51 TGGGCGCCGC TTTGTTCGGG ATGATGCACT GCGGTGCGGG CC
SBQ ID NO. 57: CM7Tcell amino acid sequence

SEQUENCE LISTING

SEQ ID No. 1 CM7 amino acid sequence
SEQ ID No. 2 CM7 DNA sequence
SEQ ID No. 3 DNA sequence
1 CGACCATCGC CAACGGTGAT TTCACCTCTA TCAGTCGCGA GTATTTTCAC
SEQ ID No. 4 DNA sequence
1 GTGAAAATAC TCGCGACTGA TAGAGGTGAA ATCACCGTTG GCGATGGTCG
SEQ ID No. 5 DNA sequence
1 GACCTACCAC TGCAATCTGG GTAGCCGTGG TAAAAAGGTG TTTGAGC
SEQ ID No. 6 DNA sequence
1 GCTCAAACAC CTTTTTACCA CGGCTACCCA GATTGCAGTG GTAGGTC
SEQ ID No. 7 DNA sequence
1 GCACTAGCAA AGACGATCAA GTGGG
SEQ ID No. 8 DNA sequence
1 CCCACTTGAT CGTCtTTgCT AGTGC
SEQ ID No. 9 CM1 amino acid sequence
SEQ ID No. 10 CM1 DNA sequence
SEQ ID No. 11 CM2 amino acid sequence
SEQ ID No. 12 CM2 DNA sequence
SEQ ID No. 13 CM3 amino acid sequence
SEQ ID No. 14 CM3 DNA sequence
SEQ ID No. 15 CM5 amino acid sequence
SEQ ID No. 16 CM5 DNA sequence
SEQ ID No. 17 CM6 amino acid sequence
SEQ ID No. 18 CM6 DNA sequence
SEQ ID No. 19 CM8 amino acid sequence
SEQ ID No. 20 CM8 DNA sequence
SEQ ID No. 21 CM9 amino acid sequence
SEQ ID No. 22 CM9 DNA sequence
SEQ ID No. 23 CM10 amino acid sequence
SEQ ID No. 24 CM10 DNA sequence
SEQ ID No. 25 CM12 amino acid sequence
SEQ ID No. 26 CM12 DNA sequence
SEQ ID No. 27 CM13 amino acid sequence
SEQ ID No. 28 CM13 DNA sequence
SEQ ID No. 29 CM14 amino acid sequence
SEQ ID No. 30 CM14 DNA sequence
SEQ ID No. 31 CM7/cys amino acid sequence
SEQ ID No. 32 DNA sequence
1 CTGGAGCGGG CCCGCACCGC AGTGCATCAT CCCGAACAAA TGCTAATAAA AGC
SEQ ID No. 33 DNA sequence
1 GCTTTTATTA GCATTTGTTC GGGATGATGC ACTGCGGTGC GGGCCCGCTC CAG
SEQ ID No. 34 CM7/Cys-s-s-[MSWP-1] amino acid sequence
SEQ ID No. 35: Amino acid sequence of peptide used in MSWP synthesis
1 Gly Ser Ser Lys Ser Pro Ser Lys Lys Lys
11 Lys Lys Lys Pro Gly Asp Cys NH₂
SEQ ID No. 36 CM15/cys amino acid sequence
SEQ ID No. 37 DNA sequence
1 CAGTGCAACG TGCCGGAATG G
SEQ ID No. 38 DNA sequence
1 CCATTCCGGA ACGTTGCACT G
SEQ ID No. 39 DNA sequence
1 GACTGATGAT TTTGAGTTCC
SEQ ID No. 40 DNA sequence
1 GGAACTCAAA ATCATCAGTC
SEQ ID No. 41 DNA sequence
1 GTCTGGACTA GTGCTAAGGA CAAGTGCAAA CGTAAATCTT GTCG
SEQ ID No. 42 DNA sequence
1 CGACAAGATT TACGTTTGCA CTTGTCCTTA GCACTAGTCC AGAC
SEQ ID No. 43 DNA sequence
1 CGGCATGGCG CATGTGATCA AAGATATCCA GTTCCGATCG CAAATTAAAT
51 ATTCTTGTCC TAAGGGTTAC CGTC
SEQ ID No. 44 DNA sequence
1 GACGGTAACC CTTAGGACAA GAATATTTAA TTTGCGATCG GAACTGGATA
51 TCTTTGATCA CATGCGCCAT GCCG
SEQ ID No. 45 DNA sequence
1 CATCTCTGGT AATACTGTCA TTTGGGATAA TAAAACACCG GTTTGTGACC
SEQ ID No. 46 DNA sequence
1 GGTCACAAAC CGGTGTTTTA TTATCCCAAA TGACAGTATT ACCAGAGATG
SEQ ID No. 47 DNA sequence
1 GACCGAATTA TCTGTGGTCT G
SEQ ID No. 48 DNA sequence
1 CAGACCACAG ATAATTCGGT C
SEQ ID No. 49 CM15/cys-MSWP1 amino acid sequence
SEQ ID No. 50 CM16/cys amino acid sequence
SEQ ID No. 51 CM16/cys-MSWP1 amino acid sequence
Seq ID No. 52 DNA sequence
1 CGCACCGCAG TGCATCATCC CGAACAAAGA TGGCCCGAGC GAAATTCTGC
51 GTGGCGATTT TAGCAGCTGC TA
Seq ID No. 53 DNA sequence
1 AGCTTAGCAG CTGCTAAAAT CGCCACGCAG AATTTCGCTC GGGCCATCTT
51 TGTTCGGGAT GATGCACTGC GGTGCGGGCC
SEQ ID NO. 54: CM7rgdcys amino acid sequence
Seq ID No. 55 DNA sequence
1 CGCACCGCAG TGCATCATCC CGAACAAAGC GGCGCCCAGC GTGATTGGCT
51 TCCGTATTCT GCTGCTGAAA GTGGCGGGCT GATA
Seq ID No. 56 DNA sequence
1 AGCTTATCAG CCCGCCACTT TCAGCAGCAG AATACGGAAG CCAATCACGC
51 TGGGCGCCGC TTTGTTCGGG ATGATGCACT GCGGTGCGGG CC
SEQ ID NO. 57: CM7Tcell amino acid sequence

Claims

A soluble polypeptide comprising, in sequence, three short consensus repeats (SCR), one SCR selected from each of SCR 1,2 and 3 of long homologous repeat A (LHR-A) as the only structurally and functionally intact SCR domains of CR1, in which ten of the native amino acids of SCR3 are substituted with the following: Ala 132, Thr 137, Ile 139, Ser 140, Tyr 143, His 153, Leu 156, Arg 159, Lys 161, Lys 177: wherein the numbering is from glutamine as residue 1 of mature CR1, and the amino-acid indicated is that which replaces the native CR1 residue at the position specified.
A polypeptide according to claim 1 having the amino acid sequence SEQ ID NO:1.
A polypeptide which is SEQ ID NO: 34.
A polypeptide which is SEQ ID NO: 31, 54 or 57.
A process for preparing a polypeptide according to any of claims 1 to 4 which process comprises expressing DNA encoding said polypeptide in a recombinant host cell and recovering the product.
A DNA polymer comprising a nucleotide sequence that encodes the polypeptide of any of claims 1 to 4.
A DNA polymer according to claim 6 having the nucleic acid sequence SEQ ID NO:2.
A replicable expression vector capable, in the host cell, of expressing the DNA polymer of claim 6 or 7.
A host cell transformed with a replicable expression vector of claim 8.
A process for preparing a soluble derivative of the soluble polypeptide of any of claims 1 to 2, said derivative comprising two or more heterologous membrane binding elements with low membrane affinity covalently associated with the polypeptide, which elements are capable of interacting independently and with thermodynamic additivity with components of cellular membranes exposed to extracellular fluids, which process comprises expressing DNA encoding the polypeptide portion of said derivative in a recombinant host cell and recovering the product and thereafter post translationally modifying the polypeptide to chemically introduce membrane binding elements.
A process according to claim 10 comprising introducing two to eight membrane binding elements selected from: fatty acid derivatives; ligands of known integral membrane proteins; sequences derived from the complementarity-determining region of monoclonal antibodies raised against epitopes of membrane proteins; membrane binding sequences identified through screening of random chemical libraries.
A pharmaceutical composition comprising a therapeutically effective amount of a polypeptide of any of claims 1 to 4 or a derivative obtainable by any of the processes of claims 10 or 11, and a pharmaceutically acceptable carrier or excipient.
The use of a polypeptide of any of claims 1 to 4 or a derivative obtainable by any of the processes of claims 10 or 11 in the manufacture of a medicament for the treatment of a disease or disorder associated with inflammation or inappropriate complement activation.